Calibrating device, mapping method and compensation method using the same

ABSTRACT

A calibrating device including a pixel unit array and a pattern is provided. The pixel unit array comprises parallel warp lines and parallel weft lines. Each warp line crosses each weft line to define pixel units all over the pixel unit array. The pattern comprises some pixel units having a gray level different from a gray level of remainder pixel units in the pixel unit array. The pattern comprises spaced bars parallel to one another and not parallel to the warp lines and the weft lines. A characteristic of the pattern is utilized to define target pixel units and comparison pixel units, and the comparison procedure is implemented with the characteristic of the pattern. Positions and gap sizes of gaps between image sensors are mapped out by comparing the target pixel units with the comparison pixel units. The quality of a scanned image is improved with compensation for the gaps.

FIELD OF THE INVENTION

The present invention generally relates to a calibrating device for animage sensor, a mapping method and a compensation method using the same,and more particularly to a calibrating device for a contact imagesensor, a mapping method and a compensation method using the same.

DESCRIPTION OF THE RELATED ART

Image sensors used in scanners today mainly include charge-coupleddevice (CCD), contact image sensor (CIS), photomultiplier tube (PMT) andcomplementary metal oxide semiconductor (CMOS), wherein the CCD and theCIS are widely used in scanners.

In general, the CCD converts light into analog voltage signals and marksup grayscales of each pixel, and then an analog/digital converterconverts the analog voltage signals into digital signals. Light providedby a light source must be reflected by mirrors and focused by opticallenses in an imaging process, thus the optical devices increase thetotal manufacturing cost of the scanner, and the light needs to betransmitted by a complicated optical path of a set of an optical system,including a light source and a plurality of mirrors and optical lenses,to form an image on a surface of the CCD. In addition, the light needsto be transmitted by a set of the mirrors and the optical lenses to formthe image on a surface of the CCD, so as to result in color deviationand optical aberration and the color usually need to be corrected byscan software. However, since the scanner with the CCD uses opticallenses to form the image on the surface of the CCD, the depth of fieldis deeper and the quality of the generated image is better, even araising spine of a book or other articles may be scanned to generate aclear scan result.

On the other hand, after light provided by a light source disposedwithin the scanner irradiates on the original image and is reflectedthereby, the CIS senses the reflected light and converts light signalsinto electrical signals, an analog/digital conversion circuit located ona bottom plate of the scanner converts electrical signals into digitalsignals, and then the digital signals are transmitted to a computer tocomplete a whole scan process. Since the reflected light reflected bythe original image can form an image on the CIS directly without themirror and the optical lens, the total manufacturing cost of the scannerwith the CIS is lower. The structure, the principle and the optical pathof the scanner with the CIS are all simple, since the light source, thesensor and the amplifier thereof are integrated. Furthermore, since thereflected light reflected by a surface of the original image forms theimage on the CIS directly, in theory, no color deviation and opticalaberration is occurred, and the scan result is closest to the originalimage.

However, the scanner with the CIS has no mirror and optical lens, theCIS have to scan the original image closely, thus scan accuracy islower, and quality of the scan result is lower than that scanned by thescanner with the CCD. Even so, the scanner with the CIS assured a placein the scanner market since it is lighter, thinner and easier to becarried, thus it is important to improve the scan result that scannedthereby.

SUMMARY OF THE INVENTION

There are lots of factors may result in poor scan result. Take thescanner with the CIS for instance, some inaccuracy, such as tolerancesin a packaging process of the CIS, may result in non-uniform gapsbetween the CISs, and then discontinuous dispositions of the CISs resultin a discontinuous scan result. Therefore, the present inventionprovides a calibrating device for gaps between image sensors and amapping method using the same to improve the scan result by using apattern of the calibrating device and a calculation to determinepositions and sizes of the gaps between the image sensors, so as tocompensate the scan result according to the positions and the sizes ofthe gaps.

In addition, all gaps, comprising shift gaps along an arrangement lineof image sensors and alignment gaps offsetting the image sensors fromthe arrangement line, result in the discontinuous scan result. Thus, thepresent invention provides a calibrating device for the gaps between theimage sensors and a compensation method using the same to compensate theshift gaps and the alignment gaps by using a pattern of the calibratingdevice to identify positions of the gaps and using pixel sizes and pixelnumbers to determine gap sizes, so as to compensate the scan resultaccording to the positions and the sizes of the gaps.

Accordingly, one embodiment provides a calibrating device comprising apixel unit array and a pattern. The pixel unit array comprises aplurality of warp lines parallel to one another and a plurality of weftlines parallel to one another, wherein each warp line crosses each weftline to define a plurality of pixel units all over the pixel unit array.The pattern comprises some pixel units having a gray level differentfrom a gray level of remainder pixel units in the pixel unit array,wherein the pattern comprises a plurality of spaced bars parallel to oneanother and not parallel to the warp lines and the weft lines

In addition, another embodiment provides a method for mapping a gapbetween image sensors comprising the following steps. A scanned image ofthe foregoing calibrating device is obtained first. Then a comparisonprocedure is set, which comprises utilizing a characteristic of thepattern to define a target pixel unit and a comparison pixel unit first,and then counting a number of the target pixel units whose gray levelsare different than the gray levels of the comparison pixel unit toobtain a value. Thereafter, the comparison procedure is implemented tothe scanned image. After that, a gap size is determined according to thevalue, and then a coordinate and the gap size relative to thecalibrating device where the gray levels of the target pixel unit aredifferent from the comparison pixel unit are stored. Then the result ofthe method for mapping the gap between the image sensors may further beapplied to a method for compensating a scanned image, so as to insert apixel value into a scanned image of an object according to thecoordinate and the gap size after the scanned image of the object isobtained.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1A illustrates an image sensor arrangement for illustrating acalibrating device and a method for compensating a scanned imageaccording to an embodiment of the present invention.

FIG. 1B illustrates an image sensor arrangement according to anotherembodiment of the present invention.

FIG. 2A illustrates a calibrating device according to an embodiment ofthe present invention.

FIG. 2B illustrates a scanned image of a calibrating device according toan embodiment of the present invention.

FIG. 2C illustrates a scanned image of a calibrating device according toanother embodiment of the present invention.

FIG. 3A illustrates a flowchart of a method for mapping gaps of an imagesensor according to an embodiment of the present invention.

FIG. 3B illustrates a flowchart of a method for compensating a scannedimage by utilizing the result of FIG. 3A according to an embodiment ofthe present invention.

DETAILED DESCRIPTION OF THE INVENTION

Reference will now be made in detail to specific embodiments of thepresent invention. Examples of these embodiments are illustrated in theaccompanying drawings. While the invention will be described inconjunction with these specific embodiments, it will be understood thatit is not intended to limit the invention to these embodiments. In fact,it is intended to cover alternatives, modifications, and equivalents asmay be included within the spirit and scope of the invention as definedby the appended claims. In the following description, numerous specificdetails are set forth in order to provide a through understanding of thepresent invention. The present invention may be practiced without someor all of these specific details. In other instances, well-known processoperations are not described in detail in order not to obscure thepresent invention.

FIG. 1A illustrates an image sensor arrangement for illustrating acalibrating device and a method for compensating a scanned imageaccording to an embodiment of the present invention. Referring to FIG.1A, a plurality of image sensors 101 are disposed on a substrate 10. Inactual application, the image sensors 101 may be formed continuouslywithout gaps, so as to form a plurality of segments 12 arranged end toend on the substrate 10 to define a first direction X, and a shift gap103 may exist between each two adjacent segments 12 from end to endrespectively. Note that in an actual situation, the image sensors 101may also be formed on the substrate 10 without forming the segments 12,but each two adjacent image sensors 101 may have a shift gap 103there-between, so as to define a first direction X, too. In addition,each two shift gaps 103 formed between two adjacent segments 12 or twoadjacent image sensors 101 may be the same or different to one anotheraccording to the actual assembling situation.

FIG. 1B illustrates an image sensor arrangement according to anotherembodiment of the present invention. Referring to FIG. 1B, a pluralityof segments 12 or image sensors 101 are also arranged along the firstdirection X but offsetting a distance, so as to form gaps between eachtwo adjacent segments 12 or each two image sensors 101 respectively.Herein, the distance between each two adjacent segments 12 or each twoimage sensors 101 relative to a second direction Y is an alignment gap105 and that relative to the first direction X is a shift gap 103.Therefore, the calibrating device and the method for compensating ascanned image of the present invention may also apply to the imagesensor arrangement as illustrated in FIG. 1B. Accordingly, alldiscontinuousness of the scanned image resulted from the shift gaps 103relative to the first direction X and the alignment gaps 105 relative tothe second direction Y may be compensated by the calibrating device andthe method for compensating the scanned image of the present inventionto enhance a quality of the scanned image, no matter how the segments 12an the image sensors 101 are arranged.

FIG. 2A illustrates a calibrating device according to an embodiment ofthe present invention. Referring to FIG. 2A, a calibrating device 20 hasa two-dimensional size, for example a rectangular shape with A4 (210mm×294 mm) size. In addition, there are a plurality of warp lines 201parallel to one another and a plurality of weft lines 203 parallel toone another, which are arranged all over the calibrating device 20. Eachwarp line 201 crosses each weft line 203 to define a plurality ofintersection points, and four intersection points define a pixel unit205 with the warp lines 201 and the weft lines 203, wherein the pixelunits 205 are arranged all over the calibrating device 20 to form apixel unit array, and sizes and shapes thereof are equal to one another.Note that the warp lines 201 or the weft lines 203 may be straight linesor curves, the calibrating device 20 illustrated in FIG. 2A is apartially enlarged view of an actual calibrating device, and the warplines and the weft lines would not be formed thereon. In the presentembodiment, n straight lines (n is a positive integer) parallel to thearrangement direction X of the image sensors (not shown in FIG. 2A) aredefined as the warp lines 201, and m straight lines (m is a positiveinteger) are defined as the weft lines 203 and cross the warp lines 201to form the pixel units 205 with rectangular shapes. The intersectionpoints are marked from (0,0) at an upper left corner of the calibratingdevice 20 to (n,0) at an upper right corner of the calibrating device20, to (0,m) at a lower left corner of the calibrating device 20, and to(n,m) at a lower right corner of the calibrating device 20, but thesequence of the marks are not limited herein. Furthermore, thecalibrating device 20 may be divided into a background and a patternwith clearly different gray levels there-between, so as to be applied toa calculation thereafter. In an embodiment, colors of the background andthe pattern are but not limited to whole white and whole black, forexample the colors may be instead of colors with different gray levelsbesides black and white.

Note that a base unit of the pattern is a pixel unit 205 filled withblack color. In addition, in the present embodiment, some continuouspixel units 205 filled with black color are formed as a spaced bar 207not parallel to the warp lines 201 and the weft lines 203. In grantview, an include angle formed between each spaced bar 207 and each warpline 201 or each weft line 203 is not equal to 0° and 90°. However, thespaced bars 207 may be straight lines as illustrated in FIG. 2A orcurves not shown herein, thus we can know that the present invention isnot limited to the previous embodiment. In addition, besides the spacedbars 207, the calibrating device 20 further comprises a transverse bar209 parallel to the weft line 203 and separate from all spaced bars 207.Moreover, a length of the transverse bar 209 is substantially equal to awhole length of the adjacent segments 12 or the image sensors 101, inother words, the length of the transverse bar 209 is substantially equalto an edge of the pixel unit array. Furthermore, in microscopic view,the spaced bars 207 may have jagged edges as illustrated in FIG. 2A arewith, but are smooth straight lines with slopes in users' view.Accordingly, the pattern of the calibrating device 20 may be used formapping the shift gaps and the alignment gaps.

FIG. 2B illustrates a scanned image of a calibrating device according toan embodiment of the present invention. After the calibrating device asillustrated in FIG. 2A is scanned by the image sensors as illustrated inFIG. 1A or FIG. 1B, the scanned image of the calibrating device isdifferent from the original calibrating device relative to where theshift gaps are located on. Referring to FIG. 2B, the pixel units 205 arechecked one by one from top to bottom and from left to right. In thefollowing embodiment, the pixel units 205 are represented as thosecoordinates. The comparison procedure to compare a target pixel unit(0,a) with a lower right comparison pixel unit (1,a+1) is start from thepixel unit (0,0) to (0,m), wherein a is a positive integer. In thepresent embodiment, the colors of the pixel units (0,0) and (1,1) areboth black, the colors of the pixel units (0,1) and (1,2) are bothblack, and the comparison procedure is repeated until the last targetpixel unit (0,m). If each target pixel unit (0,a) and its comparisonpixel unit (1,a+1) are both black or both white, there is no shift gapbetween the image sensors or the segments relative to the 0^(th) lineand the 1^(st) line of the scanned image. Then the comparison procedureis repeated to compare the pixel units between the 1^(st) line and the2^(nd) line of the scanned image, and that there is no shift gap betweenthe image sensors or the segments relative to the 1^(st) line and the2^(nd) line of the scanned image. The comparison procedure is repeatedto compare the target pixel unit (3,2) and its comparison pixel unit(4,3) until it is found that the color of the pixel unit (3,2) is blackand that of the pixel unit (4,3) is white. Therefore, there is a shiftgap between the image sensors or the segments relative to the 3^(rd)line and the 4^(th) line of the scanned image, and a size of the shiftgap is defined as one pixel unit. Thereafter, the comparison procedureis repeated to compare the lower target pixel unit (3,3) and itscomparison pixel unit (4,4) until it is found that the colors of thetarget pixel unit and its comparison pixel unit are both black or bothwhite, and if one of the colors of the pixel units is white and theother one is black, the size of the shift gap is added up with one morepixel unit. In the present embodiment, the colors of the target pixelunit (3,3) and its comparison pixel unit (4,4) are both black, thus thesize of the shift gap is equal to one pixel unit. After all target pixelunits are compared with those comparison pixel units, all comparisonresults are recorded on a memory or any kind of storage devices. Inshort, the comparison procedure is used to compare whether or not thegray levels of the target pixel unit and its comparison pixel unit ofthe scanned image is the same according to a characteristic of thepattern of the calibrating device as illustrated in FIG. 2A. Take apattern with 45° (the included angle between the warp lines and the weftlines) straight lines for instance, the characteristic thereof is theslope of the straight lines equal to an absolute value 0.5, so thecomparison pixel unit is a pixel unit adjacent to the target pixel unitand located on an extending line of a diagonal line of the target pixelunit. Therefore, the comparison procedure compares whether or not thegray levels of the target pixel unit and the adjacent comparison pixelunit located on the extending line of the diagonal line of the targetpixel unit is the same, so as to count the size of the shift gap betweenthe image sensors or the segments according to the different gray levelsituation. The comparison results can be recorded on a memory or anykind of storage devices. Therefore, in the following scanning process,the scanned image of an object relative to where the shift gaps locatedon can be compensated according to the comparison results, so as toenhance the quality of the scanned image.

On the other hand, the pattern of the calibrating device may have acharacteristic with two or more variables, for example a pattern withcurves. Thus, users may establish a table according to coordinates ofthe target pixel units relative to its comparison pixel units first, andthen map out whether or not the shift gaps exist according to the datarecorded in the table after the calibrating device is scanned.Understandable, users may also map out the shift gaps by tables even thepattern of the calibrating device have a characteristic with only onevariable. In a word, the process of mapping out the shift gaps is butnot limited to be implanted immediately or indirectly by using thetable.

In addition, the transverse bar 209 may be used for mapping out whetheror not the image sensors or the segments are aligned to one anotheraccording to whether or not the gray levels of the target pixel unit andthe adjacent comparison pixel unit is the same. Similar to the processof mapping out the shift gaps, there is an alignment gap between theimage sensors or the segments when the gray levels of the target pixelunit and the adjacent comparison pixel unit are different.

FIG. 2C illustrates a scanned image of a calibrating device according toanother embodiment of the present invention. FIG. 2C is similar to FIG.2B besides a resolution of the scanned image of the calibrating devicein FIG. 2C is larger than that of FIG. 2B. Thus, the size of the pixelunit as illustrated in FIG. 2C is smaller than that as illustrated inFIG. 2B. Note that the scanned image of the object should be compensatedrelative to the resolution of the scanned image of the calibratingdevice. Thus, the method can map out the shift gaps and the alignmentgaps regardless whether the calibrating device is scanned with any kindof scan resolution. Referring to FIG. 2C, some gray levels of the targetpixel units of the transverse bar 209 are different from that of thoseadjacent comparison pixel units. Thus, there are alignment gaps betweenthe image sensors or the segments.

FIG. 3A illustrates a flowchart of a method for mapping gaps of an imagesensor according to an embodiment of the present invention. Referring toFIG. 3A, a calibrating device is provided (step 30), wherein thecalibrating device in the present embodiment has a background and apattern with different gray levels. The calibrating device is scanned toobtain a scanned image of the calibrating device (step 32), and thereare some discrepancies between the scanned image and the originalpattern of the calibrating device when there is a shift gap or analignment gap between the image sensors of a scanner. A gray level of atarget pixel unit of the scanned image is compared with that of itscomparison pixel unit (step 34) according to a comparison procedure,which defines the target pixel unit and the comparison pixel unitaccording to a characteristic of the pattern of the calibrating device.When the gray level of any target pixel unit is the same as that of itscomparison pixel unit, the relative location has no shift gap andalignment gap between the image sensors of the scanner; otherwise, therelative location have shift gaps and alignment gaps between the imagesensors of the scanner. Thereafter, the size and the location of the gapare determined according to the scan result (step 36), which comprisescounting the gap size according to the number of the target pixel unitswhose the gray levels are different from the gray levels of thecomparison pixel unit, and then storing a coordinate and the gap sizerelative to the calibrating device in the scanner or an storage deviceof other apparatus, for example a memory or a hard desk of a scanner.

FIG. 3B illustrates a flowchart of a method for compensating a scannedimage by utilizing the result of FIG. 3A according to an embodiment ofthe present invention. Referring to FIG. 3B, an object is scanned by ascanner (step 38). A scanned image of the object is compensatedaccording to the coordinates and the gap sizes of the scanned image ofthe calibrating device (step 40). In an embodiment, the gap size isequal to one pixel unit, thus the scanned image of the object iscompensated by inserting a pixel value into each pixel unit of each linerelative to each gap, wherein the pixel value is, but not limited to, anaverage value of two pixel values at two sides of the gap. Accordingly,the compensated scanned image is more completed and smoother, thus thequality of the compensated scanned image is better.

Although specific embodiments of the present invention have beendescribed, it will be understood by those of skill in the art that thereare other embodiments that are equivalent to the described embodiments.Accordingly, it is to be understood that the invention is not to belimited by the specific illustrated embodiments, but only by the scopeof the appended claims.

1. A calibrating device, comprising: a pixel unit array comprising: aplurality of warp lines parallel to one another; and a plurality of weftlines parallel to one another, wherein each of said warp lines crosseseach of said weft lines to define a plurality of pixel units all oversaid pixel unit array; and a pattern comprising some of said pixel unitshaving a gray level different from a gray level of remainder said pixelunits in said pixel unit array, wherein said pattern comprises aplurality of spaced bars parallel to one another and not parallel tosaid warp lines and said weft lines.
 2. The calibrating device asclaimed in claim 1, wherein said pattern further comprises a transversebar parallel to said warp lines or said weft lines, and a length of saidtransverse bar is equal to a length of an edge of said pixel unit array.3. The calibrating device as claimed in claim 2, wherein said transversebar is separate from said spaced bars.
 4. The calibrating device asclaimed in claim 1, wherein included angles formed between said spacedbars and said warp lines or said weft lines are equal to 45°.
 5. Thecalibrating device as claimed in claim 1, wherein each of said pixelunits comprises a rectangular contour.
 6. The calibrating device asclaimed in claim 1, wherein said warp lines or said weft lines arestraight lines.
 7. The calibrating device as claimed in claim 1, whereinsaid warp lines or said weft lines are curve.
 8. The calibrating deviceas claimed in claim 1, wherein a color of said pixel units forconsisting said pattern is black, and a color of remainder said pixelunits is white.
 9. A method for mapping a gap between image sensors,comprising: providing a calibrating device comprising: a pixel unitarray comprising: a plurality of warp lines parallel to one another; anda plurality of weft lines parallel to one another, wherein each of saidwarp lines crosses each of said weft lines to define a plurality ofpixel units all over said pixel unit array; and a pattern comprisingsome of said pixel units having a gray level different from a gray levelof remainder said pixel units in said pixel unit array, wherein saidpattern comprises a plurality of spaced bars parallel to one another andnot parallel to said warp lines and said weft lines; obtaining a scannedimage of said calibrating device; setting a comparison procedurecomprising: utilizing a characteristic of said pattern to define atarget pixel unit and a comparison pixel unit; counting a number of saidtarget pixel units whose said gray levels are different than said graylevels of said comparison pixel unit to obtain a value; implementingsaid comparison procedure to said scanned image; and determining a gapsize according to said value and storing a coordinate and said gap sizerelative to said calibrating device where said gray levels of saidtarget pixel unit and said comparison pixel unit are different.
 10. Themethod as claimed in claim 9, wherein said step of providing saidcalibrating device further comprises setting a color of said pixel unitsfor consisting said pattern is black, and a color of remainder saidpixel units is white.
 11. The method as claimed in claim 9, wherein saidcharacteristic of said pattern means said spaced bars are straightlines, and said step of setting said comparison procedure furthercomprises determining slops of said spaced bars, so as to let saidcomparison pixel units located on extending lines of diagonal lines ofsaid target pixel units respectively.
 12. A method for compensating ascanned image, comprising: providing a calibrating device comprising: apixel unit array comprising: a plurality of warp lines parallel to oneanother; and a plurality of weft lines parallel to one another, whereineach of said warp lines crosses each of said weft lines to define aplurality of pixel units all over said pixel unit array; and a patterncomprising some of said pixel units having a gray level different from agray level of remainder said pixel units in said pixel unit array,wherein said pattern comprises a plurality of spaced bars parallel toone another and not parallel to said warp lines and said weft lines;obtaining a scanned image of said calibrating device and a scanned imageof an object; setting a comparison procedure comprising: utilizing acharacteristic of said pattern to define a target pixel unit and acomparison pixel unit; counting a number of said target pixel unitswhose said gray levels are different than said gray levels of saidcomparison pixel unit to obtain a value; implementing said comparisonprocedure to said scanned image of said calibrating device; determininga gap size according to said value and storing a coordinate and said gapsize relative to said calibrating device where said gray levels of saidtarget pixel unit and said comparison pixel unit are different; andinserting a pixel value into said scanned image of said object accordingto said coordinate and said gap size.